Autonomous monitoring system based on magnetic field variation, allowing uncrushable material to be predicted, anticipated and detected in real time and their associated methods

ABSTRACT

1.—It is disclosed an autonomous monitoring system based on a magnetic field variation: (a) that allows (i) predicting wear, failures and cracks in mining equipment; (ii) prevent and detect, in real time, uncrushable material such as metal and/or material from “old mining” or past operations and/or parts or pieces of mining equipment; (b) to be used/installed in mining and/or loading equipment, such as, but not limited to, cables shovel, hydraulic shovel, a loader or other type of loader; (c) that allows detecting strange metal bodies, and also, knowing the level of wear and/or detecting a failure or fracture in the parts of these equipment almost immediately, particularly, but not limited to, the teeth or part of them, preventing unscheduled stops and accidents of the personnel, and improving effectiveness and efficiency in the planning of predictive and preventative maintenance operations; 
     2.—an installation method of the system.
 
3.—an operating method of the system.
 
4.—tooth, ground engaging tool or part of a mining and/or loading equipment, which comprises one or more monitoring devices.

BACKGROUND OF THE INVENTION

The mining industry has tried since the early days, not only optimizing the effectiveness and efficiency of all processes, but also reducing at least accidents of staff and also minimizing the arrests of mining processes, breakdowns and the destruction of mining equipment. Also, in order to ensure the highest possible degree of safety for people working on a task, it is necessary to prevent accidents resulting from wear of mining equipment. A constant search of solutions that solve this problem have been the attempts and some inventions to predict wear in such equipment before failure or breakage of materials and, consequently, possible accidents mentioned above. It has also been trying to avoid “hindering” the production process with material that should not participate in the process and that may appear in any mining operation due to a failure or breakage of a mining equipment or part of it, or due to the existence of “old mining”. These elements are important in all the stages of the mining process, i.e. in the exploration, drilling and blasting, loading and transportation, even in the phase of winning and processing of mineral (processing plant).

In this context, and particularly at the stage of loading and transportation, a critical variables are not only finding odd metallic bodies or elements, inherited from “old mining”, but also a permanent wearing and failures or risks of breaks of teeth and other components of shovels and loaders. These, because of their nature, undergo continuous wear due to impacts, high pressures and abrasions which are subjected at the time they are used for removal, loading and material movement. In case of failure or breakage of these, such pieces or parts of the teeth and other components of the shovels and wheel loaders, become into uncrushable metal pieces, which should not reach the process lines. These pieces are as resistant and uncrushable as the metallic compounds from the “old mining”.

All these unwanted uncrushable metal elements are just called “uncrushables” since rock crushers, along with the different stages of the production line, cannot neither crush nor mill normally. If such is the case, it is likely to break or damage the crusher and, moreover, it is necessary to stop all the ongoing process with economic, technical and time consuming consequences that any stop implies. Furthermore, this stop will force maintenance personnel to enter to the crushing zone in order to remove the unwanted material, and if it is possible to repair the crusher and, consequently, the personnel working nearby could risk their health or life.

Indeed, if any of these uncrushables goes inside the bucket shovel or loader, will be deposited inside the dump truck, which will take them to the conveyor belts and then to the primary crusher and other units that process minerals.

Either in Chile or in the rest of the world, unscheduled stops due to the presence of these uncrushables constitute an unsolved problem or implementations of uncorrect solutions. Prevention systems that monitor bucket teeth breaking are ineffective and do not allow monitoring any other kind of uncrushable. Besides, it also does not aim to solve the fundamental problem which consists in determining at the moment of the failure of the shovel or piece or tooth, if this part or piece transforms it, by the fact of the event, into an uncrushable, that will be deposited inside or outside the mining shovel bucket. If this information is available, it could prevent the entry of uncrushables into the mining shovels buckets, the trucks, or other places of stock or transportation, preventing the advance of these materials to the crushing area, and other steps and equipment associated to the mining process.

Thus, the real-time detection of uncrushable material is, in general, a high importance issue in the mining industry, so it is desirable to have a system and method to monitor and detect this type of unwanted material, as soon as possible, ideally in real time.

The development of an autonomous monitoring system based on the magnetic field variation allows predicting, preventing and detecting in real time uncrushable material such as metal and/or “old mining” material or previous operations and/or parts or components of mining equipment, all the former strange bodies and uncrushable metal of mining equipment and/or loading; installation procedures; operations; and tooth, ground engaging tool or part of a mining equipment and/or loader that compromises one or more monitoring devices. Thus, the proposed autonomous system deserves to be protected, since it aims to directly solve a fundamental problem of unscheduled stops due to the appearance of these uncrushables elements in the mining industry.

In summary, it is desirable to have:

1.—an autonomous monitoring system by the magnetic field variation:

a.—that allows: i.—predicting wear, failures and breakages of mining equipment; ii.—prevents and detects, in real time, uncrushable material such as metal and/or “old mining” material or previous operations and/or parts or pieces of mining equipment;

b.—for being used/installed in extraction mining equipment and/or loading, such as, but not limited to, a cables shovel, a hydraulic shovel, a wheel loader or other kind of loader;

c—that allows, by one hand, detecting strange metallic bodies, and also to know the level of wear and/or detect almost immediately a crack or fracture or breaks of some parts of these equipment, particularly, but not limited to teeth or parts of it, avoiding unscheduled stops and accidents of personnel, and improving effectiveness and efficiency in the planning of predictive and preventive maintenance;

2.—installation method of the system;

3.—operation method of the system; and

4.—tooth, ground engaging tool or part of a mining equipment and/or loader that compromises one or more monitoring devices.

After checking the prior art, among the closest documents that we have found, and worthy to be cited, we can mention the document U.S. Pat. No. 8,284,096. This document discloses a system and method for detecting uncrushable that basically works as a pulse-echo system. The installation of an antenna is proposed inside a shovel bucket or loader, which periodically emits an intense electromagnetic signal and waits for the electromagnetic echo generated by a possible uncrushable. The document states that the antenna must reach about 2000 volts to generate the emission pulse. This implies that the system must necessarily be fed by cable. The hostile environment in which the piece works, hostility due to forces, pressures and abrasion, makes unfeasible that the proposed equipment lasts over time.

Also, the prior art disclosed in U.S. Pat. No. 8,411,930 B2, a system and method for detecting missing parts of a damaged machine. The system includes a device installed on the machine that captures images of it and an image processor. The method works by acquiring images of the machine periodically and the identification of damaged parts is made by software. This detection system has the disadvantage that during mineral extraction the visibility that covers the teeth is lost because of dust, dirt and rocks.

WO 2013033164 A1 discloses a method for monitoring the position of a tooth of a heavy-duty machine by coupling a label (TAG) of radiofrequency identification technology (RFID). A RFID reader provides the information when a tooth that has a TAG is removed from the machine. The TAGs must be integrated inside the teeth in order to detect detachment. The inclusion of these elements within the teeth creates difficulties of communication with the external antenna. System operation requires a sufficiently deep destruction of the tooth in order to reach the TAG that is inside. If the tooth is broken and does not reach or destroys the TAG in the inside, the detached metallic element will not be detected, being the main problem of this technology.

Finally, the document WO2016008059 is equivalent to CL201401897 discloses a monitoring system for detecting ferromagnetic elements hidden in the loaded ore during loading and/or unloading of a container. However, such a system is installed in the bucket of a loader and/or truck, which means to hole the bucket to set the sensors and their respective protective devices, which means intervening a high cost element such as the bucket these characteristics, unlike the present application that uses as a key or critical element the teeth or other ground engaging tool of the mining equipment. Also, the proposed invention in that document does not allow predicting the wear of a part or piece of mining equipment. Finally, this invention does not consider the incorporation of means of magnetization for teeth, ground engaging tools or any piece of mining equipment.

Definitely, the prior art does not offer an effective solution to the technical problem, related to detect properly an uncrushable material, using the proposed system and method, which will be described in detail in the following paragraphs.

BRIEF DESCRIPTION OF THE INVENTION

It presents 1.—An autonomous monitoring system based on a magnetic field variation: (a) that allows (i) predicting wear, failures and cracks in mining equipment; (ii) prevent and detect, in real time, uncrushable material such as metal and/or material from “old mining” or past operations and/or parts or pieces of mining equipment; (b) to be used/installed in mining and/or loading equipment, such as, but not limited to, cables shovel, hydraulic shovel, a loader or other type of loader; (c) that allows detecting strange metal bodies, and also, knowing the level of wear and/or detecting a failure or fracture in the parts of these equipment almost immediately, particularly, but not limited to, the teeth or part of them, preventing unscheduled stops and accidents of the personnel, and improving effectiveness and efficiency in the planning of predictive and preventative maintenance operations;

2.—an installation method of the system.

3.—an operating method of the system.

4.—tooth, ground engaging tool or part of a mining and/or loading equipment, which comprises one or more monitoring devices.

DETAILED DESCRIPTION OF THE INVENTION

The base of the system and the methodology of the current application is the use of a device composed by magnetic sensors that are strategically arranged, and that can detect magnetic field variations during the extraction process, or loading or movement. The arrangement can be made, for example, in the tooth of a shovel or bucket, or in other elements used for extraction, loading and movement of the ore. In the case of implementing, for example, the sensors in the tooth of a shovel, these will detect magnetic field variations indicating the “state” of the tooth and consequently also possible fracture or break of it or part of it.

Continuing with the same example of the device positioned in a preferred mode in a tooth of a shovel, the monitoring of each tooth is performed in real time, and determines either the wear rate or the status of a fracture or break, sending such information to one or more hardware/software centers, which maintain updated information of the status of each tooth.

Always with the same example, when working, the tooth of the shovel “will feel” any material or strange and uncrushable metal body, coming from previous mining operations or from “old mining”.

When the device detects a strange or uncrushable metal body or when an event of fracture or break occurs, transforming a tooth or a portion of it in an odd and uncrushable metal body, the system will notify the operator of the shovel and the maintenance unit, allowing to deposit the load that compromises the strange metal body in another place and thus preventing the presence of the uncrushable material inside the bucket or the truck or the conveyor belt or any other equipment, allowing the operator to redirect the load or according to of any particular protocol of the mining company.

To facilitate the understanding of the constructive and functional characteristics of the present invention, it is described with the following figures, always using the example of the device in a tooth of a shovel.

FIG. 1: shows a complete diagram of the system of the present invention.

FIG. 2 shows a complete diagram of the autonomous system of the present invention.

FIG. 3 shows a complete diagram of the device of the present invention.

FIG. 4 shows a simulation of tooth fracture in loading equipment.

FIG. 1 shows a general outline of the present invention, which is shown schematically the equipment in the field with the proposed technology. It is possible to appreciate the communication among the equipment in the field and the monitoring and acquisition central station, so that monitoring is performed for each tooth in real time, updating the information and the status of each tooth.

As shown in this figure, monitoring the status of each tooth will allow the communication of the monitoring and data acquisition central station, either with the entities that the maintenance center considered appropriate such as maintenance units, the processing plant and other critical areas, for, thus redirect the load, performing a predictive, preventive or corrective maintenance to loading equipment, or updating the databases of the ore and their final destination.

FIG. 2 shows a diagram with the main elements of the autonomous system, such as one or many devices implemented inside each tooth or ground engaging tool, the monitoring station, the warning alarms, and the means to perform the updates.

FIG. 3 shows a diagram with main elements of the device of the present invention, such as magnetic field sensors, means to perform magnetization, means to perform the communication, and the means to power up along with the associated electronics used in the system.

FIG. 4 shows a simulation of a fracture of a tooth of loading equipment, which allows monitoring of each tooth in real time and will determine the state of their fracture or break. Such information, as mentioned above, will be sent to the monitoring and data acquisition station, updating the current state of each tooth. The cited figure shows a computational simulation that exemplifies the lines of the magnetic field in a section of the mining shovel, where four teeth and part of a bucket are included. FIG. 4(a) and FIG. 4(b) show the variations of the magnetic field lines before and after, respectively, produced by the loss of one of teeth of the shovel. In the figure, the colors represent the change in intensity of the magnetic field in arbitrary units.

Detection of uncrushable entering to the bucket will be performed similarly to the method described above. The methodology is based on a similar concept to that used for metal detectors (eg. detection airport metal) consisting of sensors that detect magnetic fields produced by Foucault currents that are induced by applying a variable magnetic field over a conductor, or by relative movement of a conductive metal against a source of magnetic field. Unlike that method, herein a constant magnetic field created by means of magnetization, which will induce an electrical Foucault current whenever a uncrushable (metallic conductor) enters the magnetic field region. That is, the movement of the uncrushable will be used to induce a magnetic field variation to be detected by the sensors.

A first embodiment of the present invention, an autonomous monitoring system by magnetic field variation is proposed:

(a) that allows (i) predicting wear, failures and cracks in mining equipment; (ii) prevent and detect, in real time, uncrushable material such as metal and/or material from “old mining” or past operations and/or parts or pieces of mining equipment; (b) to be used/installed in mining and/or loading equipment, such as, but not limited to, cables shovel, hydraulic shovel, a loader or other type of loader; (c) that allows detecting strange metal bodies, and also, knowing the level of wear and/or detecting a failure or fracture in the parts of these equipment almost immediately, particularly, but not limited to, the teeth or part of them, preventing unscheduled stops and accidents of the personnel, and improving effectiveness and efficiency in the planning of predictive and preventative maintenance operations;

Such system described above comprises, firstly, one or more devices installed inside the teeth, ground engaging tools, or another part of mining and/or loading equipment or both, wherein such device comprises: a1) one or more magnetic field and/or magnetic flux sensors that allow to constantly measure magnetic field variations in teeth, ground engaging tools or other mining and/or loading equipment; a2) means to perform magnetization over the teeth, ground engaging tools or another part of an mining and/or loading equipment; a3) means to communicate the information obtained by one or more sensors to the monitoring and data acquisition station, related to the level of wear, and the status of a possible fracture or failure; a4) means to power up; and a5) associated electronics.

The devices described above allow the sensors to remain in the piece that is being monitoring and not be detached, break or fracture due to wear from the operation itself. These sensors will allow detecting in real time the presence of strange bodies or uncrushable metal, as to either determine in real time the status of ground engaging tools in mining equipment or to detect an entry of uncrushable material to the bucket of such mining equipment.

This device is comprised in the essential element of the present invention, since this is the one that allows having a permanent tracking of the conditions of the each part of the equipment.

Moreover, the system comprises one or more monitoring and data acquisition central stations, composed by hardware and software, and means to send warnings and/or alarms to the operator of mining equipment, in such a way that at the moment when an equipment, or part of it, breaks, that piece could be separated, not allowing the entrance of an uncrushable material into the stages of crushing, milling and/or any other process after ore loading.

The system also comprises means to keep the status information updated in each tooth, ground engaging tool or any other part of the equipment through a constant sweep query.

A second embodiment of the invention, a method of installing an autonomous monitoring system for mining equipment is presented, by magnetic field variation: (a) that allows (i) predicting wear, failures and cracks in mining equipment; (ii) prevent and detect, in real time, uncrushable material such as metal and/or material from “old mining” or past operations and/or parts or pieces of mining equipment; (b) to be used/installed in mining and/or loading equipment, such as, but not limited to, cables shovel, hydraulic shovel, a loader or other type of loader; (c) that allows detecting strange metal bodies, and also, knowing the level of wear and/or detecting a failure or fracture in the parts of these equipment almost immediately, particularly, but not limited to, the teeth or part of them, preventing unscheduled stops and accidents of the personnel, and improving effectiveness and efficiency in the planning of predictive and preventative maintenance operations;

Such method comprises, firstly, the installation of one or more devices inside the teeth, ground engaging tools or another part of a mining equipment, in a position of low pressure and abrasion against frontal stresses, such location is defined by modeling the safest zones of the tooth, ground engaging tool or another part of the equipment. Such device comprises: one or more magnetic field and/or magnetic flux sensors, means to perform magnetization over teeth, ground engaging tool or any other part of mining and/or loading equipment. Modeling allows the cited (one or more) sensors above to remain inside the piece to be monitored and not to fall down, get destroyed or break down due to wear from the operation itself. These sensors will allow detecting in real time either the state of the ground engaging tools in mining equipment or the entry of uncrushable material into the bucket of such mining equipment; means for constantly measure magnetic field variations in teeth, ground engaging tools or any other part of mining and/or loading equipment; means for sending the obtained information by one or more sensors, to the monitoring and data acquisition station, related to wear level and the state of an eventual fracture or rupture. The installation of such devices is done on strategic places of the teeth, ground engaging tools or any other part of mining and/or loading equipment to determine in real time either the state of the ground engaging tools in mining equipment or an entry of uncrushable material into the bucket of such mining equipment.

The following stages of the installation method correspond to test the communication of one or more devices with one or more monitoring and data acquisition stations, according to the mine sites assigned frequency; device calibration; and finally verify testing sequence.

Similarly, this method could comprise resetting the system once an event of a uncrushable detection occurs. Also, it could be reset at each shift change.

A third embodiment of the invention, a method for operating an autonomous monitoring system through magnetic field variation is presented: (a) that allows (i) predicting wear, failures and cracks in mining equipment; (ii) prevent and detect, in real time, uncrushable material such as metal and/or material from “old mining” or past operations and/or parts or pieces of mining equipment; (b) to be used/installed in mining and/or loading equipment, such as, but not limited to, cables shovel, hydraulic shovel, a loader or other type of loader; (c) that allows detecting strange metal bodies, and also, knowing the level of wear and/or detecting a failure or fracture in the parts of these equipment almost immediately, particularly, but not limited to, the teeth or part of them, preventing unscheduled stops and accidents of the personnel, and improving effectiveness and efficiency in the planning of predictive and preventative maintenance operations;

This operation method comprises continuous measurements of magnetic field variation in the teeth, ground engaging tools or any other part of mining and/or loading equipment; through the acquired information by one or more magnetic field/flux sensors inside a device that is installed within the teeth, ground engaging tools or any other part of mining and/or loading equipment, in a position of low pressure and abrasion against frontal stresses, such location is defined by modeling the safest zones of the tooth, ground engaging tool or another part of the equipment; in order to keep the device fixed and protected in the safest place of the piece and to remain attached to the piece to be monitored and do not fall off due to impacts, high pressures and abrasions, in order to determine in real time the status of the ground engaging tools in mining equipment and to detect an entry of uncrushable material into the bucket of such mining equipment.

Also, the operation method comprises the monitoring of teeth state, ground engaging tools or any other part of mining and/or loading equipment; send information to a monitoring and data acquisition central station, related to wear level, and state of an eventual fracture or rupture; give warnings and/or alarms to the operator of a mining machine, in such a way, that at the moment when an equipment, or part of it, breaks, breaks, that piece could be separated, not allowing the entrance of an uncrushable material into the stages of crushing, milling and/or any other process after ore loading; and to keep the status information updated in each tooth, ground engaging tool or any other part of the equipment through a constant sweep query.

Finally, a tooth, a ground engaging tool or any other part of mining and/or loading equipment with one or more devices are presented, comprising:

a) that allows (i) predicting wear, failures and cracks in mining equipment; (ii) prevent and detect, in real time, uncrushable material such as metal and/or material from “old mining” or past operations and/or parts or pieces of mining equipment; (b) to be used/installed in mining and/or loading equipment, such as, but not limited to, cables shovel, hydraulic shovel, a loader or other type of loader; (c) that allows detecting strange metal bodies, and also, knowing the level of wear and/or detecting a failure or fracture in the parts of these equipment almost immediately, particularly, but not limited to, the teeth or part of them, preventing unscheduled stops and accidents of the personnel, and improving effectiveness and efficiency in the planning of predictive and preventative maintenance operations;

The ground engaging tool mentioned above or any other part of mining equipment comprises as fundamental part, a) a device installed inside the tooth, ground engaging tool or any other part of mining and/or loading equipment, in a low pressure and abrasion location against frontal stresses, in a position of low pressure and abrasion against frontal stresses, such location is defined by modeling the safest zones of the tooth, ground engaging tool or another part of the equipment, where such device comprises: a1) one or more magnetic field and/or magnetic flux sensors that allow to constantly measure magnetic field variations in teeth, ground engaging tools or other mining and/or loading equipment; a2) means to perform magnetization over the teeth, ground engaging tools or another part of an mining and/or loading equipment; a3) means to communicate the information obtained by one or more sensors to the monitoring and data acquisition station, related to the level of wear, and the status of a possible fracture or failure; a4) means to power up; and a5) associated electronics.

After the detailed description of the present invention on their four embodiments, in the next section the set of claims with system and method categories are presented, along with the technical detail of each embodiment, that is to say, autonomous system; installation method; operation method; and tooth, ground engaging tool or any other part of mining and/or loading equipment. 

What is claimed:
 1. An autonomous monitoring system based on a magnetic field variation for predicting, preventing, and detecting in real time uncrushable material such as metal, “old mining” material from previous operations, parts or pieces from mining equipment, all said previous metallic and uncrushable materials for mining and/or loading equipment, such as, but not limited to a cables shovel, a hydraulic shovel, a wheel loader or any other loader, allowing, from one hand to detect strange metallic bodies and also to know the degree of wear, detecting a crack, fracture, breakage of parts of such equipment, preferably, but not limited to teeth or part of them, avoiding unscheduled stops and accidents of the personnel, and improving effectiveness and efficiency in planning predictive and preventive maintenance, characterized in that the system comprised: a) one or more devices installed inside the teeth, ground engaging tools or any other part of mining and/or loading equipment, wherein said device(s) comprising: a1) one or more field and/or magnetic flux sensors allowing constantly measuring magnetic field variations in said teeth, ground engaging tools, and other parts of the mining and/or loading equipment; a2) means for magnetizing said teeth, said ground engaging tools or any other mining and/or loading equipment; a3) means for communicating information obtained by said one or more sensor to the monitoring and data acquisition station, related to the detection of strange and uncrushable materials, wear level, an eventual state of fracture or breakage or both; a4) means of powering; a5) associated electronics; wherein said device enables one or more sensors remain in the part in which they are installed and not released or break due to operation itself; where these sensors will allow detecting in real time the existence of strange bodies and uncrushable metal and determining in real time a state of ground engaging tools of mining equipment and detecting an entry of any uncrushable material to the bucket of said mining equipment; b) one or more monitoring and data acquisition stations composed by hardware/software; c) means to give a warning and/or alarm signal to an operator of the mining machine, so that at the moment that an anomalous and uncrushable metal body, the detachment of a part or both, breakage fracture or break of said mining equipment is detected, it can be separated from the rest of the material, preventing the entry of said body to the stages of crushing, milling, loading and/or any subsequent stage; d) Means to keep updated the information of the state of each tooth, means of wear or other part of the equipment through a routine or sweeping process or constant query.
 2. The system according to claim 1, wherein said mining equipment corresponds to a cables shovel.
 3. The system according to claim 1, wherein said mining equipment corresponds to a hydraulic shovel.
 4. The system according to claim 1, wherein said mining equipment corresponds to a loader.
 5. The system according to claim 1, wherein said mining equipment corresponds to a bucket.
 6. The system according to claim 1, wherein said mining equipment corresponds to a dump truck.
 7. The system according to claim 1, wherein said mining equipment corresponds to a chute.
 8. The system according to claim 1, wherein said monitoring or data acquisition central comprising one or more graphical user interfaces or display means.
 9. The system according to claim 1, wherein the device is located at one or more strategic points of the tooth, element of waste or other part of mining extraction equipment, which, like the disposition of the main claim, has a low probability of fracture.
 10. The system according to claim 1, wherein the means for magnetizing comprise magnetic field induction by electric current.
 11. The system according to claim 1, wherein the means for magnetizing comprise means that include bringing a ferromagnetic material or magnet, or magnetic field generator to a magnetizable region.
 12. The system according to claim 1, wherein said means for magnetizing comprise means that include coils.
 13. The system according to claim 1, wherein said means for sending information obtained by one or more sensors, to the monitoring and data acquisition central, comprising wireless communication means.
 14. The system according to claim 1, wherein said means for sending information obtained by said one or more sensors to the monitoring and data acquisition central , comprising wired communication.
 15. The system according to claim 1, wherein the means for constantly measuring the magnetic field variations comprise magnetic field induction means by electric current.
 16. The system according to claim 1, wherein the means for constantly measuring the magnetic field variations comprise means of induction of electric current by variations of magnetic field
 17. The system according to claim 1, wherein the means for constantly measuring the magnetic field variations comprise means of induction of electric current by variations of magnetic field
 18. The system according to claim 1, wherein said means for constantly measuring variations in magnetic field, comprising means including semiconductor magnetic field and/or magneto-resistive, metal sensors or both.
 19. The system according to claim 1, wherein said feeding means may also comprise self-rechargeable systems based thermoelectric modules, electric induction modules, piezoelectric modules, electromechanical modules or any combination thereof.
 20. Method of installation of an autonomous monitoring system based on a magnetic field variation that allows to predict, prevent and detect in real time uncrushable or pieces that arise from the mining equipment, all the above, metallic and inchancables bodies for mining extraction equipment and/or load, such as, but not limited to cable shovels, hydraulic shovels, front loader, or other type of loader which it allows, on one hand, to detect the strange metallic bodies and also to know the level of breakage and/or to detect a fracture or rupture of parts of these equipment, in particular, but not limited to the teeth or parts thereof, avoiding unscheduled downtimes and accidents with field personnel, and improving the effectiveness and efficiency in the planning of preventative and preventive maintenance, characterized by a method with the following stages: a1) Installing one or more devices within teeth, ground engaging tools or other part of said mining, equipment at a position of low pressure and abrasion against frontal stresses, position defined by a previous modeling of a “safe areas” of the tooth, said wear member or other part of the equipment, wherein said device(s) comprise: al) one or more magnetic field and/or magnetic flux sensors that allow constantly measuring magnetic field variations in teeth, ground engaging tools or other mining and/or loading equipment; a2) means for magnetizing said teeth, said ground engaging tools or other mining and/or loading equipment; a3) means for communicating information obtained by said one or more sensors to a monitoring and data acquisition central, related to the detection of strange and uncrushable and/or the wear, fracture or breakage of an metallic element, or both; a4) feeding means; a5) associated electronics; wherein said device enables said one or more sensors to remain in the part in which they are installed and do not bankrupt, detach or break product of the wear characteristic of the operation; where these sensors allow to detect in real time the existence of strange and inchancable metallic bodies, as well as to determine in real time the state of the ground engaging tools of the mining equipment and to detect the entry of uncrashable material into the bucket of said mining equipment, test the communication of one or more devices with one or more monitoring and data acquisition central, according to the frequency assigned by the mining site b) testing communication; c) calibrating the device; d) verify testing sequence.
 21. The method according to claim 20, wherein the method further comprises resetting said system once the detection event of an inchancable occurs.
 22. The method according to claim 20, wherein the method further comprises resetting said system at each shift change.
 23. Method of operation of an autonomous monitoring system based on magnetic field variation that allows predicting, preventing and detecting in real time uncruschable material, such as metal and/or “old mining” material coming from previous work and/or parts or pieces that arise from the mining equipment, all the previous strange and uncrashable metallic bodies, for mining and/or loading equipment, such as, but not limited to, a cable shovel a hydraulic shovel, a front loader or other loader, allowing, from one hand, detecting metallic strange bodies and also to know the degree of wear, and/or detecting a cracking, fracturing, or breaking or a combination of parts from such equipment, preferably, but not limited to teeth, ground engaging tools or other parts of mining equipment, loading or both, avoiding unscheduled downtime and accidents with field personnel, and improving effectiveness and efficiency in planning predictive and preventive maintenance, comprising the following steps: a) Continuously measuring changes in the magnetic field in teeth, ground engaging tools or other mining and/or loading equipment, or both; using information captured by said one or more magnetic field or flux sensors installed in a device installed inside teeth, ground engaging tools or other part of mining and/or loading equipment or both, in a low pressure and abrasion position against frontal stresses. Position is defined by a prior modeling of the “safe areas” of a tooth, said wear element or other part of said equipment; so that said device is secured and protected in the safest place of the work piece allowing it to remain in the part to be monitored, avoiding detachment due to impacts, high pressures and abrasions, to determine in real time a state of ground engaging tools of mining equipment and detecting an entry of uncrushable material into the bucket; b) monitoring the state of teeth, ground engaging tools or other mining or loading equipment, or both; c) sending information to a monitoring and data acquisition central about the wear level, and the possibility of a fracture or breakage; d) giving a warning or alarm signal or both to the operator of said mining machine, so that at the moment when a detachment, a cracking, fracturing or breaking of a part of the mining equipment, or a metal from “old mining” is detected, the involved pieces can be separated from equipment, preventing in this way the entry of such uncrushable material to the steps of crushing, milling, or any subsequent step to loading ore; e) Keeping the information of the state of each tooth updated through a routine process or constant consultation.
 24. The method according to claim 23, characterized in that step d) will allow the operator of the loading equipment to redirect the load to a sector specially destined for that purpose, and in this way will not enter said “contaminated” charge to the truck or other mining equipment.
 25. A tooth, a wear element, or other part of a mining or loading equipment, or both, comprising one or more devices that, by the magnetic field variation, allow predicting, preventing and detecting in real time uncrushable material such as metal, “old mining” material coming from previous work, parts coming from mining equipment or combinations thereof, all said previous strange and uncrushable metallic material for mining and loading equipment, avoiding unscheduled downtime and accidents with field personnel, and improving effectiveness and efficiency in the planning of predictive and preventive maintenance, wherein said wear element or another part of mining equipment comprises: a) one or more devices installed inside a tooth, said wear member or other part of mining equipment, at a position of low pressure and abrasion against frontal stresses, position defined by prior modeling of the safer zones of a tooth, said wear element or other part of the equipment, wherein said device(s) comprising: a1) one or more field and/or magnetic flux sensors that allow continuous measurement of magnetic field variations in teeth, ground engaging tools, or other mining and/or loading equipment; a2) means for magnetizing the teeth, the ground engaging tools or other mining and/or loading parts of equipment; a3) means for communicating said information obtained by said one or more sensors, to the monitoring and data acquisition central, in relation to the detection of strange and uncrushable or wear level metal bodies or both and/or the state of eventual fracture or breakage; a4) feeding means; a5) associated electronics; wherein said device enables said one or more sensors remain in the part in which they are installed avoiding their detachment, fracture or breakage due to own operation; where, these sensors allow detecting in real time the existence of strange and uncrushable metallic parts, and determining in real time the state of ground engaging tools of mining equipment and detecting the entry of uncrushable material into the bucket of such mining equipment; means to give a warning or alarm signal or both to an operator of an mining equipment, so that at the moment when the detachment, cracking, fracturing or breaking of a part of the mining equipment is detected or a metallic part coming from “old mining” is detected, it can be separated from the equipment, preventing the entry of said uncrushable material to the crushing, milling, and any subsequent step to loading ore; b) means for maintaining current state information of each tooth, wear element or other part of said equipment through a routine or screening process or constant sweep query. 